Communication system, communication device, communication server, computer-readable storage medium and method of controlling a connection between the communication device and an access point

ABSTRACT

A communication system comprises a communication device; an access point (AP); and a communication server is provided. The communication system performs a method comprising: acquiring first information including movement information of the communication device; acquiring second information including position information of the AP; determining a connectable time corresponding to a length of time the communication device moves within a communicable range of the AP on the basis of the first information and the second information; and controlling a connection between the communication device and the AP on the basis of the connectable time.

CROSS-REFERENCE TO RELATED APPLICATION(S)

This application claims priority to and the benefit of Japanese PatentApplication No. 2019-233361 filed on Dec. 24, 2019, the entiredisclosure of which is incorporated herein by reference.

BACKGROUND OF THE INVENTION Field of the Invention

The present invention relates to a communication system, a communicationdevice, a communication server, and a method of controlling the same anda computer-readable storage medium.

Description of the Related Art

A known communication system for controlling connections determines abase station capable of communicating with a communication deviceinstalled in a vehicle from position information of the communicationdevice and position information of the base station. The technologydescribed in Japanese Patent Laid-Open No. 2005-341311 determines aconnection destination on the basis of position information of acommunication device and communication result information.

However, when the communication device is moving, the connection may beinterrupted in a short amount of time even if the communication deviceis connected to a closely-located base station.

SUMMARY OF THE INVENTION

In light of the problem described above, an object of the presentinvention is to provide a system capable of increasing the length oftime a communication device and a base station are connected.

A communication system according to the present invention comprises: acommunication device; an access point (AP); and a communication serverwherein the communication system performs a method comprising: acquiringfirst information including movement information of the communicationdevice; acquiring second information including position information ofthe AP; determining a connectable time corresponding to a length of timethe communication device moves within a communicable range of the AP onthe basis of the first information and the second information; andcontrolling a connection between the communication device and the AP onthe basis of the connectable time.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a schematic view of a communication system according to afirst embodiment.

FIG. 2A is a hardware block diagram of a communication server 10according to the first embodiment.

FIG. 2B is a hardware block diagram of an access point 20 according tothe first embodiment.

FIG. 2C is a hardware block diagram of an in-vehicle device 30 accordingto the first embodiment.

FIG. 3A is a software block diagram of the communication server 10according to the first embodiment.

FIG. 3B is a software block diagram of the access point 20 according tothe first embodiment.

FIG. 3C is a software block diagram of the in-vehicle device 30according to the first embodiment.

FIG. 4 is a sequence diagram of an example of the processing of thecommunication system according to the first embodiment.

FIGS. 5A and 5B are diagrams for explaining how connectable time iscalculated according to the first embodiment.

FIG. 6 is a sequence diagram of an example of the processing of acommunication system according to a second embodiment.

DESCRIPTION OF THE EMBODIMENTS

Hereinafter, embodiments will be described in detail with reference tothe attached drawings. Note, the following embodiments are not intendedto limit the scope of the claimed invention, and limitation is not madean invention that requires a combination of all features described inthe embodiments. Two or more of the multiple features described in theembodiments may be combined as appropriate. Furthermore, the samereference numerals are given to the same or similar configurations, andredundant description thereof is omitted.

First Embodiment

FIG. 1 is a schematic view of a communication system according to anembodiment of the present invention. A communication system 1 includes acommunication server 10, an access point (AP) 20, and an in-vehicledevice 30. The in-vehicle device 30 executes processing for connectingto an appropriate AP 20, from among a plurality of connectable APs 20,by acquiring information for identifying the length of time thein-vehicle device 30 can be connected to the AP 20 from thecommunication server 10.

The communication server 10 is a computer that provides information usedto determine the length of time the in-vehicle device 30 can beconnected to the AP 20. In FIG. 1 , the communication server 10 isillustrated as a single server connected to an Internet 21. However, thefunction of the communication server 10 may be provided by a pluralityof servers connected via a network. Also, the Internet 21 may include anintranet in at least a part thereof.

The AP 20 forms a local access network and, in the case in which thein-vehicle device 30 is located within a communicable range, wirelesslycommunicates with the in-vehicle device 30, enabling communication viathe Internet 21 via the in-vehicle device 30. Note that in the presentembodiment, the AP 20 is described as proving wireless communicationwith the in-vehicle device 30 complying with Wi-Fi (registeredtrademark). However, the AP 20 may provide wireless communicationcomplying other communication protocols, such as at least one of LTE,LTE-A, or LPWA. The AP 20 is a wireless base station connected to theInternet 21 via a wired connection or a wireless connection and iscapable of communication with the communication server 10.

The in-vehicle device 30 is a communication device capable ofcommunicating via the AP 20 with a server (not illustrated) on theInternet 21 or another in-vehicle device (not illustrated). Also, thein-vehicle device 30 of the present embodiment is capable of connectingto a network provided by the AP 20. In the present specification, thein-vehicle device 30 may also be referred to as a terminal 30. In oneexample, the in-vehicle device 30 is a computer or an electronic controlunit (ECU) installed in a moving body, such as a vehicle, a watercraft,or an aircraft.

Next, an example of the hardware configuration of the communicationserver 10, the AP 20, and the terminal 30 of FIG. 1 will be describedwith reference to FIGS. 2A to 2C.

FIG. 2A is a hardware block diagram of the communication server 10. Thecommunication server 10 includes a CPU 201, random access memory (RAM)202, read only memory (ROM) 203, a hard disk drive (HDD) 204, and anetwork interface (I/F) 205. Each unit is communicatively connected toone another via an internal bus 206. The CPU 201 controls the entireprocessing of the communication server 10. The RAM 202 is a volatilestorage area and is used as the working memory of the CPU 201 or thelike. The ROM 203 is a non-volatile storage area and stores variousprograms executed by the CPU 201 and data. The HDD 204 is a non-volatilestorage area and stores various data. The network I/F 205 controlscommunication with external devices via an external network (forexample, the Internet 21) and transmits and receives various data. Inthis communication system, the communication method in terms of wired,wireless, and the like is not limited, and a combination of these may beused.

FIG. 2B is a hardware block diagram of the AP 20. The AP 20 includes aCPU 211, RAM 212, ROM 213, a HDD 214, a network I/F 215, and a sensorI/F 216. Each unit is communicatively connected to one another via aninternal bus 217. The CPU 211 is similar to the CPU 201, the RAM 212 issimilar to the RAM 202, the ROM 213 is similar to the ROM 203, and theHDD 214 is similar to the HDD 204. Thus, description thereof will beomitted. The network I/F 215 controls communication with externaldevices via an external network (for example, the Internet 21) andincludes at least one network I/F for transmitting and receiving variousdata. Also, the network I/F 215 includes a wireless network I/F capableof communication with the terminal 30 located in the communicable range.The sensor I/F 216 is an interface for acquiring the state of the AP 20from a sensor (not illustrated) provided in the AP 20 or a sensor (notillustrated) connected to the AP 20. In the present embodiment, thesensor I/F 216 includes a global positioning system (GPS) sensor, andthe CPU 211 acquires position information of the AP 20 via a sensor I/F.In an example, the sensor I/F 216 may be connected to an accelerationsensor. Also, the sensor I/F 216 may be capable of acquiringinformation, such as the number of terminals connected to the networkformed by the AP 20, throughput, and the like, as load information ofthe network formed by the AP 20. Note that in the case in which the AP20 is moving, movement route information may be stored in the HDD 214 oran input/output I/F that receives movement route information from anexternal source may be provided.

FIG. 2C is a hardware block diagram of the terminal 30. The terminal 30includes a CPU 221, RAM 222, ROM 223, a HDD 224, a network i/F 225, asensor I/F 226, and an input/output I/F 227. Each unit iscommunicatively connected to one another via an internal bus 228. TheCPU 221 is similar to the CPU 201, the RAM 222 is similar to the RAM202, the ROM 223 is similar to the ROM 203, and the HDD 224 is similarto the HDD 204. Thus, description thereof will be omitted. The networkI/F 225 controls communication with external devices via an externalnetwork (for example, the Internet 21) and includes at least one networkI/F for transmitting and receiving various data. Note that the networkI/F 225 according to the present embodiment includes a short-range radiocommunication network I/F capable of connection with a short-range radiocommunication network provided by the AP 20 and a wide area wirelessnetwork I/F capable of communication with a wide area wirelesscommunication network such as a mobile communication network. Theterminal 30 can communicate with the communication server 10 via thewide area wireless network I/F and connect to a network formed by the AP20 via the short-range radio communication network I/F. In one example,the network I/F 225 includes a wireless environment measurement functionand is capable of measuring signal intensity and/or wireless quality(noise intensity such as signal-to-interference plus noise power ratio(SINR) and the like) from the AP 20 located within the communicablerange. The sensor I/F 226 includes a GPS sensor, and the CPU 221acquires position information of the terminal 30 via the sensor I/F 226.In another example, the sensor I/F 226 may detect the communicationamount required by the terminal 30. The input/output I/F 227, forexample, is an input/output device capable of at least one ofnotification of information or reception of operation input with respectto a user of the terminal 30, such as an occupant of a vehicle installedwith the terminal 30. In one example, the input/output I/F 227 is aninput device including at least one of a display device, such as adisplay, or a speaker. In another example, the input/output I/F 227 isan output device including at least one of a button, keys, a camera, atouch panel display, or a microphone. In an example, the terminal 30 iscapable of acquiring a planned travel route of the vehicle installedwith the terminal 30 via the input/output I/F 227.

Software Configuration

FIG. 3A is a diagram illustrating the software of the communicationserver 10 according to the present embodiment. The software module ofthe communication server 10 illustrated in FIG. 3A is implemented by theCPU 201 executing a program stored on the RAM 202 to control thecommunication server 10. The software module of the communication server10 is provided with an AP information management unit 301, a terminalinformation acquisition unit 302, a candidate AP determination unit 303,and a candidate AP information providing unit 304.

The AP information management unit 301 receives, from the AP 20, APinformation including at least one of position information of the AP 20described below, movement information, communicable range information,or load information and stores the AP information in a storage unit (forexample, the HDD 204). In one example, the AP information managementunit 301 may store information indicative of whether or not use of theAP 20 is permitted and/or information indicative of whether or not useof the AP 20 is recommended these pieces of information being set by theadministrator of the AP 20. Also, in one example, the AP informationmanagement unit 301 may associate with and store in the AP 20 resultinformation relating to the amount of time the terminal 30 was connectedto the AP 20 previously or the communication amount and/or evaluationinformation relating to the communication quality of the AP 20 receivedfrom the user of the terminal 30.

The terminal information acquisition unit 302 receives, from theterminal 30, terminal information including at least one of positioninformation, movement information, or wireless quality information ofthe terminal 30 (described below). The candidate AP determination unitidentifies the AP 20 capable of connection with the terminal 30 from theterminal information of the terminal 30 and the AP information. Thecandidate AP information providing unit 304 generates information(candidate AP information) used for connecting the terminal 30 to the AP20 the terminal 30 is capable of connection with and transmitting theinformation to the terminal 30.

FIG. 3B is the software configuration of the AP 20 according to thepresent embodiment. The software module of the AP 20 illustrated in FIG.3B is implemented by the CPU 211 executing a program stored on the RAM212 to control the AP 20. The software module of the AP 20 includes theposition information transmission unit 311 and a network informationtransmission unit 312. Also, the AP 20 optionally includes a movementinformation transmission unit 313 and a load information transmissionunit 314.

The position information transmission unit 311 acquires the positioninformation of the AP 20 via the sensor I/F 216 and transmits theposition information to the communication server 10. In one example, theposition information may include information of the orientation and/orheight of the AP 20. The network information transmission unit 312acquires information relating to the network formed by the AP 20 andtransmits the information to the communication server 10. In oneexample, in the case in which the AP 20 forms a wireless local areanetwork, the network information transmission unit 312 transmits theidentifier (SSID) of the access point and the password to thecommunication server 10. In another example, the network informationtransmission unit 312 may transmit, to the communication server 10,information corresponding to at least one of the directivity of theantenna of the AP 20, the transmission signal intensity of the AP 20, orthe unit type. In yet another example, the network informationtransmission unit 312 may transmit, to the communication server 10,information relating to information relating to the load of the networksuch as the communication amount within a predetermined time period ofthe network formed by the AP 20 and/or information relating to wirelessquality detected by the AP 20 (noise intensity, such assignal-to-interference plus noise power ratio (SINR), and packet lossratio). The movement information transmission unit 313 transmits, to thecommunication server 10, information relating to the movement route,such as movement direction and movement speed, in the case in which theAP 20 is moving.

FIG. 3C is the software configuration of the terminal 30 according tothe present embodiment. The software module of the terminal 30illustrated in FIG. 3C is implemented by the CPU 221 executing a programstored on the RAM 222 to control the terminal 30. The software module ofthe terminal 30 includes a movement information transmission unit 321, acandidate AP information reception unit 322, and a connection controlunit 323. Also, the terminal 30 optionally includes a wirelessenvironment information transmission unit 324.

The movement information transmission unit 321 transmits movementinformation including information of the position of the terminal 30obtained via the sensor I/F 226, movement direction, movement speed, andthe like to the communication server 10. In one example, the movementinformation may include information relating to the planned movementroute. The candidate AP information reception unit 322 receives, fromthe communication server 10, the candidate AP information used forconnecting to the connectable AP 20. The connection control unit 323uses the candidate AP information received from the communication server10, connects to the AP 20, and performs communication. The wirelessenvironment information transmission unit 324 measures the wirelessenvironment information, such as the received signal strength indicator(RSSI) and the signal-to interference plus noise power ratio (SINR),relating to the wireless environment where the terminal 30 is locatedand transmits the information to the communication server 10.

Next, an example of processing executed by the communication server 10,the AP 20, and the terminal 30 according to the present embodiment willbe described with reference to FIG. 4 . The AP 20 executes theprocessing of FIG. 4 at intervals of a predetermined amount of time.Regarding the terminal 30, when power is supplied to a vehicle installedwith the terminal 30, the processing is started by the CPU 221 executinga program stored on the RAM 222 and when the vehicle is travelling, orthe connection with the AP 20 is interrupted, or when a communicationcapacity equal to or greater than a predetermined amount per apredetermined amount of time is required to execute a streamingapplication or the like, the processing is executed again.

First, the AP 20 acquires AP information including position informationof the AP 20 and network information used for connection with the AP 20(step S401) and transmit the AP information to the communication server10 (step S402). Note that the position information and the networkinformation may be sent separately or, only in the case in which the AP20 forms the network for the first time or the network settings arechanged, the network information may be transmitted. Also, the AP 20 maytransmit the position information only in the case in which the positionof the AP 20 changes. Note that in the case in which the AP 20 ismoving, the AP information may include movement information. Also, inone example, the network information, as described above, may includeinformation relating to the transmission radio wave intensity,directivity, and unit type of the AP 20, information relating to a noiselevel detected by the AP 20, or load information of the AP 20. Next, thecommunication server 10, having received the AP information from the AP20 in step S403, moves the processing forward to step S404 and storesthe received AP information in a storage unit such as the HDD 204. Notethat, when AP information is received from the same AP 20 a number oftimes, i.e., when AP information from an AP 20 with its AP informationalready stored in the storage unit is received, the old AP informationmay be replaced with the new AP information.

Next, the terminal 30 acquires the terminal information including themovement information of the terminal 30 in step S405, and transmits theinformation to the communication server 10 in step S406. Also, in oneexample, in step S405, the terminal 30 measures the information relatingto the wireless communication quality and transmits the information tothe communication server 10. For example, the information relating tothe wireless communication quality may include an access point name(SSID) detected by the terminal 30 scanning within a predeterminedfrequency band, a reception signal intensity (RSSI) of a beacon receivedfrom an access point by the terminal 30, and the like.

Next, the communication server 10, having received the terminalinformation from the terminal 30 in step S407, moves the processingforward to step S408 and searches for the AP 20 the terminal 30 canconnect to from the received AP information and the terminalinformation. Here, from the position of the AP 20 included in the APinformation and the position of the terminal 30 included in the terminalinformation, if the AP 20 and the terminal 30 are within a predetermineddistance of one another, it can be determined that the AP 20 can connectto the terminal 30. Also, in the case in which an identifier of the AP20 can be identified using the wireless quality information such as SSIDof the detected AP, the AP 20 that the terminal 30 can connect to may beidentified from only the terminal information.

Note that the terminal 30 may actually be unable to connect to the AP 20identified by the communication server 10 in step S408 and determined tobe connectable by the terminal 30. For example, in the case in which thecommunication server 10 determines whether or not the terminal 30 andthe AP 20 are connectable from the position of the terminal 30 and theposition of the AP 20, in the processing of step S409 described below,the communication server 10 may determine that connection is notactually suitable. Note that in step S408, in the case in which it isdetermined that there are no APs 20 that the terminal 30 can connect to,the communication server 10 may transmit an error message to theterminal 30 and stop the processing from thereon. Next, the processingproceeds to step S409, and the communication server 10 calculates thelength of time the terminal 30 can be connected to the AP 20(connectable time) for each AP 20 determined to be connectable by theterminal 30.

Next, an example of a method of calculating the connectable time will bedescribed with reference to FIGS. 5A and 5B. In this example, theterminal 30 of FIG. 5A is located at a relative position (X, Y) withrespect to the AP 20 and is moving at a relative velocity (Vx, Vy) withrespect to the AP 20 at a time point to. Also, in this example, the AP20 has a communicable range 501 shaped as a perfect circle with a radiusR. Here, an estimated time of the terminal 30 entering the communicablerange 501 of the AP 20 is defined as t1 and an estimated time of leavingthe communicable range 501 is defined as t2 to give the followingEquations.(X+t1*Vx){circumflex over ( )}2+(Y+t1*Vy)=R{circumflex over ( )}2(X+t2*Vx){circumflex over ( )}2+(Y+t2*Vy)=R{circumflex over ( )}2By solving the two Equations for the estimated time t1 and t2, thecommunication server 10 can estimate the length of time t2−t1 that theterminal 30 and the AP 20 can be connected. Also, in the case in whichthe communication speed of the AP 20 can be acquired by thecommunication server 10 for example, from the communication speed andthe length of the connectable time, the communication capacity capableof being communicated by the terminal 30 connecting to the AP 20 can beestimated.

Note that in the present embodiment, the AP 20 was described as having acommunicable range shaped as a perfect circle. However, in a similarmanner, in the case in which the AP 20 or the terminal 30 is providedwith an antenna with directivity, by calculating the relative positionand the relative velocity of the AP 20 and the terminal 30 and therelative orientation, the connectable length of time can be calculated.For example, with the communicable range of the AP 20 represented by X-Ycoordinates, by determining whether or not the relative positioncoordinates (X+t*Vx, Y+t*Vy) of the terminal 30 at time t is within thecommunicable range of the AP 20, the connectable time of the terminal 30can be determined.

Note that the radius of the communicable range of the AP 20 may be avalue such as 30 m common among different APs 20, may be a valueassociated to each different unit type of the AP 20, or may be a valueassociated to each different output intensity of the AP 20. In otherwords, the communicable range of the AP 20 used for determining theconnectable time between the terminal 30 and the AP 20 by thecommunication server 10 may not be the same as the actual communicablerange of the AP 20 or may be a communicable range estimated by thecommunication server 10.

Next, in this example, the terminal 30 of FIG. 5B is travelling along aroute 511 from a time t3 and the AP 20 has a communicable range 512. Inthis example, the terminal 30 is located at a relative position (X1, Y1)with respect to the AP 20 at the time t3, the terminal 30 is travellingat a relative velocity (Vx1, Vy1) with respect to the AP 20, and, due toturning right at an estimated time t4, the terminal 30 is travellingalong a route 513 at a relative velocity (Vx2 Vy2) with respect to theAP 20. In this example, by determining whether or not the terminal 30will enter the communicable range 512 of the AP 20 between the time 3and the time t4 or after the time 14 and determining whether or not theterminal 30 will leave the communicable range 512 of the AP 20 betweenthe time t3 and the time t4 or after the time t4, the length of the timethe terminal 30 can connect to the AP 20 can be estimated.

Following on from step S409 of FIG. 4 , the processing moves forward tostep S410, and the communication server 10 determines whether or notthere is an AP for which a length of the connectable time with theterminal 30 is equal to or greater than a predetermined value from amongthe APs 20 with a calculated connectable time. The predetermined valuemay be a numerical value, such as 30 seconds, 1 minute, or the like,that is preset in the communication server 10. Alternatively, whether ornot there are a predetermined number, for example, 5, of APs 20 with aconnectable time of 10 seconds or greater listed in descending order maybe determined. Note that in step S410, in addition to the length of theconnectable time with the terminal 30, whether or not there is an APwith a communication load equal to or less than a predetermined value,whether or not there is the AP 20 that satisfies a condition other thanthe length of the connectable time, or the like may be determined. Notethat in the case in which the AP information management unit 301 of thecommunication server 10 stores the result information and/or theevaluation information of the AP 20 described above, whether or not theAP 20 satisfies a predetermined condition may be determined on the basisof at least one of the result information or the evaluation information.Also, in the case in which the communication server 10 receives thewireless environment information from the AP 20, the AP 20 with lowenvironmental noise may be selected. In this way, the communicationserver 10 can determine the AP 20 that can connect to the terminal 30 onthe basis of previous communication history of the AP 20, evaluationfrom a user, and wireless environment information of the terminal 30, inaddition to the length of the connectable time.

Next, the processing proceeds to step S411 and the communication server10 generates, as candidate AP information, information for connectionwith at least one AP 20 from among the APs 20 for which a length of theconnectable time with the terminal 30 is equal to or greater than apredetermined length and transmits the information to the terminal 30 instep S412. The candidate AP information may include at least one ofSSID, a wireless LAN password, or an IP address, for example. Also, thecandidate AP information may include a value corresponding to the lengthof the connectable time with the terminal 30. Also, in the case in whichthe communication server 10 generates the candidate AP information onthe basis of previous communication history of the AP 20, evaluationfrom a user, and wireless environment information of the terminal 30,the candidate AP information may include a value corresponding to alevel recommending a connection calculated by the communication server10.

Next, the terminal 30 executes control for connecting to the AP 20 (stepS414) on the basis of the candidate AP information received in stepS413. For example, in step S414, the terminal 30 may display thecandidate AP information via the input/output I/F 227 on the displayunit, receive a user selection of which AP 20 to connect to, and connectto the selected AP 20. Alternatively, in step S414, the terminal 30 maynotify the user via the input/output I/F 227 with a message inquiringwhether to permit connection to one of the APs 20 included in thecandidate AP information, receive permission from the user, and connectto the AP 20. Alternatively, in step S414, the terminal 30 mayautonomously connect to one of the APs 20 included in the candidate APinformation, such as the AP 20 with the longest connectable time, the AP20 with the highest level recommending connection, or the like.

As described above, the communication system 1 according to the presentembodiment determines the length of time the terminal 30 and the AP 20can be connected to one another and controls the connection between theterminal 30 and the AP 20 on the basis of the position information ofthe AP 20 and the movement information of the terminal 30. In this way,the connectable time between the terminal 30 and the AP 20 can belengthened, and the likelihood of connection being frequentlyinterrupted can be reduced.

Second Embodiment

In the communication system of the first embodiment described above, thecommunication server 10 identifies a candidate AP from terminalinformation and AP information. In the communication system of thesecond embodiment described below, the terminal 30 identifies acandidate AP from terminal information and AP information. Note thatdescription of configurations, processing, and functions that aresimilar to that of the first embodiment will be omitted.

First, the communication system according to the second embodiment willbe described with reference to FIG. 6 . The processing of step S601 tostep S608 is similar to the processing of step S401 to step S408 of thefirst embodiment illustrated in FIG. 4 , and thus description thereofwill be omitted. In step S609, the communication server 10 generatescandidate AP information of the AP 20 the terminal 30 can connect to onthe basis of the received movement information of the terminal 30 andthe position information of a plurality of APs 20 and transmits theinformation to the terminal 30 in step S610. Note that in a similarmanner as in step S408 of FIG. 4 described above, the terminal 30 mayactually be unable to connect to the AP 20 identified by thecommunication server 10 in step S608 and connectable by the terminal 30.For example, in the case in which the communication server 10 determineswhether or not the terminal 30 and the AP 20 are connectable from theposition of the terminal 30 and the position of the AP 20, in theprocessing of step S612 described below, the communication server 10 maydetermine that connection is not actually possible.

Next, the processing proceeds to step S612, and the terminal 30 thatreceived the candidate AP information transmitted from the communicationserver 10 in step S610 (step S611) calculates the connectable time foreach of the connectable APs 20 received in step S611. In step S612, acalculation method similar to the calculation method described in stepS409 of FIG. 4 is used. Next, in step S613, the terminal 30 determineswhether or not there is the AP 20 with a connectable time equal to orgreater than a predetermined length. If there is the AP 20 with aconnectable time equal to or greater than the predetermined length (Yesin step S613), the processing proceeds to step S614, and control isexecuted to control to one of the APs 20 with a connectable time equalto or greater than the predetermined length.

As described above, the terminal 30 according to the present embodimentdetermines the AP 20 connectable for a predetermined length of time orgreater from among the APs 20 that the terminal 30 can connect to on thebasis of the position information of the AP 20 and the positioninformation of the terminal 30 and connected to the AP 20. In this way,in the case of the terminal 30 connecting to the AP 20, the terminal 30can connect to the AP 20 expected to provide a connection apredetermined length of time or greater.

Other Embodiments

The invention is not limited to the embodiments described above, andvarious modifications and changes are possible within the scope of theinvention.

For example, both the communication server 10 and the terminal 30 maycalculate the length of time the terminal 30 and the AP 20 can connectto one another. In this case, the terminal 30 may connect to the AP 20when both the communication server 10 and the terminal 30 determine thatthe expected length of time the terminal 30 can be connected to the AP20 is equal to or greater than a predetermined length of time.

Also, in the present embodiment described above, the in-vehicle device30 connects to a network formed by the access point 20. However, thein-vehicle device 30 may connect to a network formed by the in-vehicledevice 30. In other words, in the case in which a single in-vehicledevice 30 functions as an access point, the communication system 1 mayexecute the processing described above to connect another in-vehicledevice 30 to the in-vehicle device 30 functioning as an access point. Inthis case, the in-vehicle device 30 functioning as an access pointexecutes the processing corresponding to step S401 and step S402 of FIG.4 .

Summary of Embodiments

1. A communication system according to the embodiment described above isa communication system (for example, the communication system 1)including:

a communication device (for example, the terminal 30); an access point(AP) (for example, the AP 20); and a communication server (for example,the communication server 10), wherein

the communication system includes

first acquisition unit configured to acquire (for example, step S407,step S607) first information including movement information of thecommunication device,

second acquisition unit configured to acquire (for example, step S403,step S603) second information including position information of the AP,

determination unit configured to determine (for example, step S409, stepS612) a connectable time corresponding to a length of time thecommunication device moves within a communicable range of the AP on thebasis of the first information and the second information, and

control unit configured to control connection between the communicationdevice and the AP on the basis of the connectable time.

In this way, a system can be provided that is capable of increasing thelength of time a communication device and a base station are connected.

2. The control unit of the embodiment described above controlsconnection between the communication device and the AP with for whichthe connectable time with the communication device is equal to orgreater than a predetermined length of time.

In this way, the length of time a communication device and a basestation are connected can be equal to or greater than a predeterminedlength of time.

3. The determination unit of the embodiment described above is includedin the communication server.

In this way, a system can be provided that is capable of increasing thelength of time a communication device and a base station are connected.

4. The determination unit of the embodiment described above is includedin the communication device.

In this way, a system can be provided that is capable of increasing thelength of time a communication device and a base station are connected.

5. The second information of the embodiment described above furtherincludes information that can identify the communicable range of the AP.

In this way, the length of time a communication device and a basestation are connected can be accurately determined.

6. The second information of the embodiment described above furtherincludes information corresponding to a transmission signal intensity ofthe AP.

In this way, the length of time a communication device and a basestation are connected can be accurately determined.

7. The second information of the embodiment described above furtherincludes information corresponding to directivity of an antenna providedin the AP.

In this way, the length of time a communication device and a basestation are connected can be accurately determined.

8. The first information according to the embodiment described aboveincludes wireless environment information relating to a wirelessenvironment measured by the communication device, and the control unitestimates a length of connectable time with the AP further on the basisof the wireless environment information.

In this way, the length of time a communication device and a basestation are connected can be accurately determined using actual wirelessenvironment information.

9. The second information of the embodiment described above furtherincludes information relating to a planned movement route of the AP.

In this way, a system can be provided that is capable of increasing thelength of time a communication device and a base station are connectedeven when the AP is moving.

10. The control unit according to the embodiment described above, in acase in which the communication device moves within the communicablerange of a plurality of the APs, displays information relating to atleast one of the plurality of APs on a display unit and receives a userselection of which one of the plurality of APs to connect to.

In this way, a system in which a communication device and a base stationcan connect on the basis of a user selection can be provided.

11. The control unit according to the embodiment described above, in acase in which the communication device moves within the communicablerange of a plurality of the APs, autonomously selects which one of theplurality of APs to connect to on the basis of the connectable time.

In this way, a system in which a communication device and a base stationcan autonomously connect can be provided.

12. A communication device according to the embodiment described aboveincludes:

transmission unit configured to transmit first information includingmovement information of the communication device to a communicationserver;

reception unit configured to receive second information includingposition information of an access point (AP) from the communicationserver:

determination unit configured to determine a connectable timecorresponding to a length of time the communication device moves withina communicable range of the AP on the basis of the first information andthe second information received by the reception unit, and

control unit configured to control connection with the AP on the basisof the connectable time determined by the determination unit.

In this way, a system can be provided that is capable of increasing thelength of time a communication device and a base station are connected.

13. A communication server according to the embodiment described aboveincludes:

first information acquisition unit configured to acquire firstinformation including movement information of a communication devicefrom the communication device:

second information acquisition unit configured to acquire secondinformation including position information of an access point (AP) fromthe AP:

determination unit configured to determine a connectable timecorresponding to a length of time the communication device moves withina communicable range of the AP on the basis of the first information andthe second information; and

transmission unit configured to generate AP information relating to theAP on the basis of the connectable time determined by the determinationunit and transmitting the AP information to the communication device.

In this way, a system can be provided that is capable of increasing thelength of time a communication device and a base station are connected.

14. A method of controlling a communication device according to theembodiment described above includes the steps of:

transmitting first information including movement information of thecommunication device to a communication server;

receiving second information including position information of an accesspoint (AP) from the communication server;

determining a connectable time corresponding to a length of time thecommunication device moves within a communicable range of the AP on thebasis of the first information and the second information received inthe receiving step; and

controlling connection with the AP on the basis of the connectable timedetermined in the determining step.

In this way, a system can be provided that is capable of increasing thelength of time a communication device and a base station are connected.

15. A method of controlling a communication server according to theembodiment described above includes the steps of:

acquiring first information including movement information of acommunication device from the communication device:

acquiring second information including position information of an accesspoint (AP) from the AP:

determining a connectable time corresponding to a length of time thecommunication device moves within a communicable range of the AP on thebasis of the first information and the second information; and

generating AP information relating to the AP on the basis of theconnectable time determined in the determining step and transmitting theAP information to the communication device.

In this way, a system can be provided that is capable of increasing thelength of time a communication device and a base station are connected.

16. A program according to the embodiment described above

causing a computer to execute a control method including the steps of:

transmitting first information including movement information of thecommunication device to a communication server;

receiving second information including position information of an accesspoint (AP) from the communication server;

determining a connectable time corresponding to a length of time thecommunication device moves within a communicable range of the AP on thebasis of the first information and the second information received inthe receiving step; and

controlling connection with the AP on the basis of the connectable timedetermined in the determining step.

In this way, a system can be provided that is capable of increasing thelength of time a communication device and a base station are connected.

17. A program according to the embodiment described above

causing a computer to execute a control method including the steps of:

acquiring first information including movement information of acommunication device from the communication device;

acquiring second information including position information of an accesspoint (AP) from the AP;

determining a connectable time corresponding to a length of time thecommunication device moves within a communicable range of the AP on thebasis of the first information and the second information; and

generating AP information relating to the AP on the basis of theconnectable time determined in the determining step and transmitting theAP information to the communication device.

In this way, a system can be provided that is capable of increasing thelength of time a communication device and a base station are connected.

What is claimed is:
 1. A communication system comprising: acommunication device; an access point (AP); and a communication serverwherein the communication system performs a method comprising: acquiringfirst information including movement information of the communicationdevice; acquiring second information including position information ofthe AP; determining a connectable time corresponding to a length of timethe communication device moves within a communicable range of the AP onthe basis of the first information and the second information; andcontrolling a connection between the communication device and the AP onthe basis of the connectable time, wherein the second informationfurther includes information relating to a planned movement route of theAP.
 2. The communication system according to claim 1, wherein thecontrolling the connection comprises controlling the connection betweenthe communication device and the AP for which the connectable time withthe communication device is equal to or greater than a predeterminedlength of time.
 3. The communication system according to claim 1,wherein the determining the connectable time is performed by thecommunication server.
 4. The communication system according to claim 1,wherein the determining the connectable time is performed by thecommunication device.
 5. The communication system according to claim 1,wherein the second information further includes information that canidentify the communicable range of the AP.
 6. The communication systemaccording to claim 5, wherein the second information further includesinformation corresponding to a transmission signal intensity of the AP.7. The communication system according to claim 5, wherein the secondinformation further includes information corresponding to directivity ofan antenna provided in the AP.
 8. The communication system according toclaim 1, wherein the first information includes wireless environmentinformation relating to a wireless environment measured by thecommunication device, and the controlling the connection comprisesestimating a length of connectable time with the AP further on the basisof the wireless environment information.
 9. The communication systemaccording to claim 1, wherein in a case in which the communicationdevice moves within the communicable range of a plurality of APs, thecontrolling the connection comprises displaying information relating toat least one of the plurality of APs on a display unit and receiving auser selection of which one of the plurality of APs to connect to. 10.The communication system according to claim 1, wherein in a case inwhich the communication device moves within the communicable range of aplurality of APs, the controlling the connection comprises autonomouslyselecting which one of the plurality of APs to connect to on the basisof the connectable time.
 11. A communication device for performing amethod comprising: transmitting first information including movementinformation of the communication device to a communication server;receiving second information including position information of an accesspoint (AP) from the communication server; determining a connectable timecorresponding to a length of time the communication device moves withina communicable range of the AP on the basis of the first information andthe second information, and controlling a connection with the AP on thebasis of the connectable time, wherein the second information furtherincludes information relating to a planned movement route of the AP. 12.A communication server for performing a method comprising: acquiringfirst information including movement information of a communicationdevice from the communication device; acquiring second informationincluding position information of an access point (AP) from the AP;determining a connectable time corresponding to a length of time thecommunication device moves within a communicable range of the AP on thebasis of the first information and the second information; andgenerating AP information relating to the AP on the basis of theconnectable time and transmitting the AP information to thecommunication device, wherein the second information further includesinformation relating to a planned movement route of the AP.
 13. A methodof controlling a communication device, the method comprising:transmitting first information including movement information of thecommunication device to a communication server; receiving secondinformation including position information of an access point (AP) fromthe communication server; determining a connectable time correspondingto a length of time the communication device moves within a communicablerange of the AP on the basis of the first information and the secondinformation; and controlling connection with the AP on the basis of theconnectable time, wherein the second information further includesinformation relating to a planned movement route of the AP.
 14. A methodof controlling a communication server, the method comprising: acquiringfirst information including movement information of a communicationdevice from the communication device; acquiring second informationincluding position information of an access point (AP) from the AP;determining a connectable time corresponding to a length of time thecommunication device moves within a communicable range of the AP on thebasis of the first information and the second information; andgenerating AP information relating to the AP on the basis of theconnectable time and transmitting the AP information to thecommunication device; wherein the second information further includesinformation relating to a planned movement route of the AP.
 15. Anon-transitory computer-readable storage medium that stores a programfor causing a computer to execute the method according to claim
 13. 16.A non-transitory computer-readable storage medium that stores a programfor causing a computer to execute the method according to claim
 14. 17.A communication system comprising: a communication device; an accesspoint (AP); and a communication server wherein the communication systemperforms a method comprising: acquiring first information includingmovement information of the communication device; acquiring secondinformation including position information of the AP; determining aconnectable time corresponding to a length of time the communicationdevice moves within a communicable range of the AP on the basis of thefirst information and the second information; and controlling aconnection between the communication device and the AP on the basis ofthe connectable time, wherein the first information further includesinformation relating to a planned movement route of the communicationdevice.
 18. A communication device for performing a method comprising:transmitting first information including movement information of thecommunication device to a communication server; receiving secondinformation including position information of an access point (AP) fromthe communication server; determining a connectable time correspondingto a length of time the communication device moves within a communicablerange of the AP on the basis of the first information and the secondinformation, and controlling a connection with the AP on the basis ofthe connectable time, wherein the first information further includesinformation relating to a planned movement route of the communicationdevice.
 19. A communication server for performing a method comprising;acquiring first information including movement information of acommunication device from the communication device; acquiring secondinformation including position information of an access point (AP) fromthe AP; determining a connectable time corresponding to a length of timethe communication device moves within a communicable range of the AP onthe basis of the first information and the second information; andgenerating AP information relating to the AP on the basis of theconnectable time and transmitting the AP information to thecommunication device, wherein the first information further includesinformation relating to a planned movement route of the communicationdevice.
 20. A method of controlling a communication device, the methodcomprising: transmitting first information including movementinformation of the communication device to a communication server;receiving second information including position information of an accesspoint (AP) from the communication server; determining a connectable timecorresponding to a length of time the communication device moves withina communicable range of the AP on the basis of the first information andthe second information; and controlling connection with the AP on thebasis of the connectable time, wherein the first information furtherincludes information relating to a planned movement route of thecommunication device.
 21. A method of controlling a communicationserver, the method comprising; acquiring first information includingmovement information of a communication device from the communicationdevice; acquiring second information including position information ofan access point (AP) from the AP; determining a connectable timecorresponding to a length of time the communication device moves withina communicable range of the AP on the basis of the first information andthe second information; and generating AP information relating to the APon the basis of the connectable time and transmitting the AP informationto the communication device, wherein the first information furtherincludes information relating to a planned movement route of thecommunication device.
 22. A non-transitory computer-readable storagemedium that stores a program for causing a computer to execute themethod according to claim
 20. 23. A non-transitory computer-readablestorage medium that stores a program for causing a computer to executethe method according to claim
 21. 24. The communication system of claim1, wherein the planned movement route further comprises a planned travelroute of a vehicle.